• ABSTRACT
• RESUMO
• INTRODUCTION
• METHODS
• RESULTS
• DISCUSSION AND CONCLUSION
• REFERENCES

ABSTRACT

Objective: To evaluate the genetic tests is fundamental for the adequate treatment of non-small cell lung cancer (NSCLC) with tyrosine kinase inhibitors (TKI). Given that access to this evaluation is still limited for those who depend on the Brazilian Public Health System, it seems important to provide regulatory agencies with epidemiological and prognostic information to guide future health policies and guidelines in Brazil. This work aims to characterize EGFR and KRAS mutations in NSCLC and associating them with patients demographic and tumor clinical-pathologic features. Methods: From 2004 to 2017, 237 metastatic NSCLC patients treated at Erasto Gäertner Cancer Hospital were included in this study. Electronic medical records were retrospectively reviewed and the mutational status EGFR and KRAS were defined. Results: We detected EGFR mutation in 20 samples (15.7%), and KRAS mutation in 26 samples (21.5%). The majority of EGFR mutations was detected within the exon 19 (n=9, 45.0%), and for KRAS G12V (n=8, 30.8%) and G12C (n=8, 30.8%) were the hotspots. The median overall survival was 11 months. We did not detect any statistical differences in survival rates between mutated and wild-type tumors neither for EGFR (p=0.898) nor for KRAS (p=0.458). Only two patients had access to TKI and were considered outliers with the best survival rates. Conclusion: We described important information about NSCLC biological behavior in a population treated in a reference public cancer center in South Brazil. Studies like this highlight the magnitude that TKI treatment could have in the overall survival of patients with NSCLC after being introduced into the SUS. Future studies that address the economic impact of this issue are also needed. Here we also make a comparison of our results with other regions of Brazil that have different genetic backgrounds to evaluate the impact of targeted therapies.

RESUMO

Objetivo: Avaliar os testes genéticos é fundamental para o tratamento adequado do câncer de pulmão de não pequenas células (CPNPC) com inibidores da tirosina quinasse (TKI). Dado que o acesso a esta avaliação ainda é limitado para aqueles que dependem do Sistema de Saúde Pública do Brasil, parece importante proporcionar às agências reguladoras informação epidemiológica y de prognóstico para guiar as políticas e diretrizes de saúde futuras no Brasil. Este trabalho tem como objetivo caracterizar as mutações de EGFR y KRAS em CPNPC y associá-las com as características demográficas y tumorais clínico-patológicas dos pacientes. Métodos: de 2004 a 2017, se incluíram neste estudo 237 pacientes com CPNPC metastático tratados no Hospital de Câncer Erasto Gäertner. Os prontuários electrónicos foram revisados retrospectivamente y se definiram os estados mutacionais EGFR y KRAS. Resultados: Detectamos a mutação EGFR em 20 amostras (15.7%) e a mutação KRAS em 26 muestras (21.5%). A maioria das mutações de EGFR foram detectadas no exão 19 (n = 9, 45.0%), y para KRAS G12V (n = 8, 30.8%) y G12C (n = 8, 30.8%) foram os pontos críticos. A mediana de supervivência global foi de 11 meses. Não detectamos nenhuma diferencia estadística nas taxas de supervivência entre tumores mutados e do tipo selvagem nem para EGFR (p = 0,898) nem para KRAS (p = 0,458). Só dois pacientes tiveram acesso à TKI y se consideraram valores atípicos com as melhores taxas de supervivência. Conclusão: descrevemos informação importante sobre o comportamento biológico do CPNPC numa população tratada em um centro público de referência de câncer no sul do Brasil. Estudos como este destacam a importância que o tratamento com TKI poderia ter na supervivência general dos pacientes com CPNPC depois da sua introdução no SUS. Também se necessitam estudos futuros que abordem o impacto económico deste problema. Aqui também realizamos uma comparação dos nossos resultados com outras regiões do Brasil que têm diferentes antecedentes genéticos para avaliar o impacto das terapias dirigidas.

INTRODUCTION

In Brazil, lung cancer is a public health problem given its high incidence, morbidity and mortality. The estimative of new cases from the Brazilian NCI is 18.740 for men and 12.530 for women in 2018[1]. Smoking cigarettes is, by far, the leading cause of this neoplasm, but efforts have been made to comprehend the genetic and inflammatory mechanisms involved in carcinogenesis and prognosis.

Clinicopathologic aspects, such as performance status (PS), comorbidities, histopathologic subtypes and oncogenic driver mutations, are crucial information to guide the initial treatment. Epidermal growth factor receptor gene ( EGFR ) and KRAS are the most known activating driver mutations, considered biomarkers predictive of response to tyrosine kinase inhibitors (TKIs), a class of drugs that confers better survival than chemotherapy and less toxicity[2].

Unfortunately, in Brazilian public health, the access to these new technologies is limited by cost, once the reimbursement from the Health Ministry is about half the cost of TKIs treatment for each NSCLC patient[3]. In this article, we describe real data on clinical and prognostic characteristics and their correlation with driver mutations in population with advanced NSCLC representative of Southern Brazil. This information has the potential to change the approach to NSCLC management in public institutions in Brazil.

METHODS

This study aims to analyze frequencies of EGFR and KRAS mutations in a NSCLC population treated at a public comprehensive cancer center in Brazil, and to correlate the tumor genotypes with demographic and clinical-pathologic features. We conducted a retrospective study of all treated patients referred to the Erasto Gäertner Cancer Hospital from January 2004 to December 2017, diagnosed as metastatic or recurrent NSCLC, according to the American Joint Committee on Cancer (AJCC) staging manual, version 7. The Erasto Gäertner Hospital at Curitiba, Paraná State, Brazil, provides cancer care to public health system and is a reference for the Southern Brazilian population. Ethics approval for the study was obtained from the local research ethics board under the inscription number 2320. The primary endpoint was to characterize EGFR and KRAS mutations in metastatic or recurrent NSCLC, suitable for palliative chemotherapy treatment. Secondary endpoints were to correlate EGFR and KRAS mutational status with individual demographic and clinical- pathologic features, and with relevant clinical endpoints (best treatment response and overall survival). The key exclusion criteria were defined with non-treated patients and cases in which formalin-fixed, paraffin-embedded tissue (FFPET) were not available or the genetic material was not viable for analyses.

By a retrospective chart review, we collected the patient's baseline and tumor characteristics, such as age, sex, ethnicity, comorbidities, smoking status, metastasis sites and histological subtypes. Ethnicity was classified as white, black or other. Registered comorbidities were chronic obstructive pulmonary disease (COPD), systemic arterial hypertension (SAH), diabetes, hypothyroidism, and second primary tumor and, for statistical analysis, they were grouped in “absent” (no comorbidity), “one or two” and “three or four” comorbidities subgroups. For smoking status, patients were classified as never smoker, previous or current smoker. The pack-years were calculated by multiplying the number of packs of cigarettes smoked per day by the number of years the person has smoked. Metastatic sites were grouped by prognostic criteria in “lung and/or pleural metastasis only” (excluding other concomitant sites), “visceral” (i.e. liver, adrenal, lymph nodes), “central nervous system (CNS)” (with or without involvement of other sites) and “bones only” (excluding other concomitant sites). The histological diagnosis was based on the 2014 World Health Organization (WHO) classification as adenocarcinoma, squamous cell carcinoma (SCC) and undifferentiated (NOS) carcinomas. The PS was estimated according to the Eastern Cooperative Oncology Group (ECOG) classification. Systemic treatment protocols, including the type of chemotherapy, were collected. Outcomes including overall survival (OS), from the time of diagnosis to death, and progression-free survival (PFS) were recorded. The duration of PFS was defined as the time from diagnosis until the date of objective disease progression or death in the absence of progression, regardless of whether the patient had received another anticancer therapy before progression.

2592 NSCLC patients were referred to our hospital from 2004-2017 and 1398 were at an advanced or recurrent disease. Only 587 were able to perform chemotherapy treatment, and 273 of those have suitable FFPET for DNA extraction and analysis. Tumor samples from primary tumor or metastatic site biopsy or pulmonary surgery resection were collected in FFPET from our Pathology Service arquives and analyzed for mutational status at the laboratory Mantis Diagnósticos Avançados, in Curitiba, Paraná State, Brazil. Reasons for not inclusions were depleted and tiny amount of tumor tissue material, and scarce or low quality DNA extracted from tumor samples interfering with the analysis. Procedures for tumor tissue microdissection and DNA extraction were done according established protocols. In summary, local pathologists defined the area of the tumor sample to be selected by optical microscopy in histological sections (stained by hematoxylineosin), and a number of tissue sections of 5-10 micra corresponding to the blocks were used for DNA extractions with the QIAmp® DNA Mini Kit (Qiagen; California, USA). Quantitative assay for KRAS gene point mutation in codons 12, 13 (exon 2) and 61 (exon 3) was performed with KRAS Pyro ® Kit (QIAGEN). The EGFR Pyro ® Kit (QIAGEN) was used for quantitative assay for EGFR point mutations in codons 719 (exon 18), 768 (exon 20), 790 (exon 20), 856-861 (exon 21) and deletion of exon 19 (del19). The analysis and identification of existing mutations in these codons were performed using the Software PyroMarK ® (QIAGEN Germany).

The quantitative variables were described by average, standard deviation, median, and amplitude. The comparison of two groups defined for the EGFR or KRAS mutation, in respect to the quantitative variables, was made using t-Student test for independent samples or non-parametric MannWhitney test. Categorical variables were analyzed considering Fisher test or Chi-Square test. Survival was described by Kaplan-Meier method and Cox regression model was used to determine mortality predictors. We excluded from the survival analysis the two outlier cases treated with gefitinib. A p-value with less than 0.05 was considered statistically significant. Statistical analyses were performed using the computational program Stata/SE v.14.1. StataCorp LP, USA.

RESULTS

Considering the 587 patients who were able to perform chemotherapy, 273 had viable FFPET for DNA extraction and a n a l y s e s and those were included in this article. The clinical characteristics of adenocarcinoma and SCC cases at baseline are presented in[Table 1].

In our population, median age was 60. White ethnicity was 93.4%, and male gender was 52.7%. The majority has at least one comorbidity (54.8%), and the most frequent was chronic obstructive pulmonary disease (COPD). Adenocarcinoma was diagnosed in 162 (59.3%), SCC in 92 (33.7%) and undifferentiated carcinomas in 19 (7.0%) patients. Previous or current smoker status was recorded in 201 cases (73.6%). Smoking was more frequent in SCC (93.5%) than adenocarcinoma (63.0%) [p value = 0.0001]. PS was 0 or 1 in 166 (60.8%) cases. CNS metastasis at diagnosis was detected in 49 (17.9%) patients for symptomatic patients based on clinical symptoms or neurological findings, since CNS scanning was not routine in our service. There is an association between gender, smoking status and metastases sites with histological subtypes (p=0.018; p<0.00001; p=0.004, respectively). The most common chemotherapy treatment scheme at first line therapy was a platinum-doublet (95.2%); docetaxel for second line regimen (63.9%); and 2 cases received Gefitinib as second line therapy (2.4%) ([Table 2]).

Of the 127 tumors tested for EGFR, 20 resulted positive for any EGFR mutation (15.7%). Among the 121 available samples for KRAS analysis (since six samples were depleted after EGFR analysis), KRAS mutation was detected in 26 (21.5%). In only one tumor sample, concomitance of EGFR (G719A) and KRAS (G12C) mutations could be detected. Compared with wildtype tumors (WT), EGFR mutated tumors did not differ in the median age at diagnosis (60 years for WT vs. 57 years, p=0.513) or in those mutated for KRAS (60 years WT vs. 59.5 years, p=0.343). We also did not found any statistical difference for gender, smoking status, pack- years, histological subtypes (adenocarcinoma or SCC) or metastatic sites between mutated and wild type subgroups for either EGFR or KRAS ([Table 3]).

Among mutated tumors for EGFR or KRAS, the most common metastatic site was visceral (35.0%) in both groups. Others metastatic sites observed in EGFR and KRAS mutated tumors were lung or pleural (30.0% and 27.0%, respectively), bones (25.0% and 19.0%, respectively), and CNS (10.0% and 19.0%, respectively). Although there was an expressive prevalence of CNS metastasis in KRAS mutated tumors compared with EGFR, frequencies did not reach statistical significance for any of those sites in both EGFR and KRAS mutated groups (p=0.838).

In our population, the most frequent position of EGFR mutations was in exon 19 (n=9, 45.0%). Other EGFR mutations were found in exon 21 (n=7, 35.0%), exon 20 (n=3, 15.0%) and exon 18 (n=1, 5.0%). In details, the mutations detected in exon 19 were del E746-A750 (n=5), del L747-P753 (insS) (n=1), del L747- A750 (insP) (n=2), and a complex deletion in-frame c.2237_2251 del15 (p.E746_ T751>A) (n=1). In exon 21, the mutation L858R (n=5) and L861Q (n=2). In exon 20, S768I (n=3); and exon 18, G719A (n=1). For KRAS, the mutations detected on available samples were G12V (n=8, 30.8%), G12C (n=8, 30.8%), G12S (n=6, 23.1%) and G12D (n=4, 15.4%). The distribution of EGFR kinase domain mutations according to clinical and pathological characteristics is described in[Table 4].

The median overall survival of the entire cohort was 11 months, and no statistical difference in survival was detected between EGFR mutated versus WT (12.4 months vs. 10.6 months; p=0.898), or KRAS mutated versus WT (12.1 months vs. 10.7 months; p=0.458). Some clinical variables significantly interfered with survival: PS 0 or 1 had more favorable prognosis than PS 2 or more (p<0.001); and lung or pleural metastatic sites had better outcomes than visceral, CNS and bones (p=0.004). Neither comorbidities number nor histological subtypes (adenocarcinoma or SCC) influenced overall survival. However, patients that had more than one metastatic site had worst prognosis compared with only one- metastatic site tumors. Kaplan-Meier curves are represented in[figure 1].

DISCUSSION AND CONCLUSION

Oncogenic drivers identification has redefined how we treat advanced NSCLC. Chemotherapy is no longer a standard therapy if a patient has an actionable driver mutation. Patients with a genotype-directed therapy have a decreased risk of death compared with patients with any oncogenic driver who did not receive genotype-directed therapy (HR, 0.69 [95% CI, 0.53-0.9], p=0.006)[4]. In this study, we aimed to determine the frequency of the most common oncogenic drivers, EGFR and KRAS, and clinical prognosis correlations.

In Brazil, EGFR mutation frequency ranges from 20 to 30%[5] and KRAS mutation is approximately 1416% in Brazil and Latin America[6] [7]. A multi-institutional Lung Cancer Mutation Consortium (LCMC) from USA[4] enrolled 1007 patients with metastatic lung adenocarcinoma and found 21% EGFR mutation and 25% KRAS mutation. In our study, EGFR mutation frequency was 15.7% and KRAS was 21.5%. A possible explanation for the low EGFR mutation frequency is the high smoking burden of our population, since EGFR mutation is more common in non-smokers or light smokers. The high smoking burden also justifies the greater KRAS mutation frequency in our population. We found no correlation with EGFR or KRAS mutation and smoking status (p=0.234 and p=0.276). The tumor blocks quality may also have influenced our results, since 53.5% of patients enrolled were ineligible, due to insufficient tissue. Considering that this is a retrospective study, when this project began, biopsies were performed only to establish a diagnosis.

In the large LCMC study[4], 28% of patients enrolled were ineligible, due to insufficient tissue and only 48% had complete genotyping performed, which demonstrates the difficulty to obtain lung tissue for molecular analysis.

Ethnicity influences EGFR and KRAS mutation frequency and treatment response. In LCMC[4], EGFR mutation were highly associated with Asian race (p<0.001) and KRAS mutation with white race (p=0.006). In our study, total white race frequency was 93.4%, mainly because European influence in South Brazil, so it was not possible to determine the ethnicity difference in EGFR or KRAS mutated patients.

According to LCMC[8], EGFR mutation is highly associated with female sex (p<0.001) and no gender association was observed in KRAS (p=0.746). In our study, we did not found correlation in EGFR or KRAS with gender (p=0.812 and p=0.826, respectively).

In LCMC[8], EGFR mutations were less associated with bone metastasis presence, and adrenal metastasis absence.

They also found that KRAS mutation was correlated with bone metastasis. Retrospective data show that patients with intrapulmonary metastasis have a higher frequency of KRAS mutation[9] than patients with extrapulmonary metastasis (35.0% vs. 26.5%, p=0.0125). In our study, we did not find this correlation, but we observed that KRAS mutation was more frequent in patients with visceral metastasis (34.6%). Possibly, if there is an association between EGFR or KRAS mutation and metastasis site, this association should be weak.

In this study, the survival was calculated between prognostic variables. Regardless mutational status, one metastasis site versus multiple metastasis sites is considered a known favorable prognostic factor, especially if it is resectable[10]. In agreement with previous studies[11], we found a higher overall survival in patients with single metastasis site versus multiple metastasis sites (p=0.018), and a higher overall survival for lung or pleural metastasis versus other metastasis sites (p = 0.004).

Another prognostic variable is PS. Initial PS evaluation is crucial for treatment choice and it affects overall survival. In our study, we reviewed only treated patients, and 60.8% of them were PS 0 or 1. This subgroup showed greater survival compared with PS 2, 3 or 4 patients (p<0.001).

Our median survival was 11 months and is similar with others survival data in Brazilian studies[5]. For EGFR we did not found survival differences between mutated and non-mutated groups (median, 12.4 months and 10.6 months, respectively, p=0.898), and as well as for KRAS (median, 12.1 months and 10.7 months, respectively, p=0.458).

Only in mid-2010, with the encouragement of pharmaceutical companies, molecular testing for advanced NSCLC adenocarcinoma started at our Institution, but public access to TKIs was still limited by costs. Thus, in our study, only two patients with EGFR mutation were treated w i t h Gefitinib, a firstgeneration EGFR TKI, in the second line treatment. These two cases were male patients, smokers, one with L858R mutation (exon 21) and one with E746-A750 mutation (exon 19). Both patients had the study longest survival rates (12.4 months and 37.1 months, respectively). This highlights the great benefit of TKI therapy in survival in NSCLC patients compared to standard chemotherapy[12] [13].

The best responses to TKI targeting EGFR are in individuals with exon 19 deletions[14]. Point mutations in exons 18 and 21 are also predictive of TKI response, but to a lesser extent and with relatively limited published experience with EGFR TKI response[15]. L861Q (exon 21) mutation has insufficient response data[16]. Some mutations in exon 20, such as T790M, are known to be associated with acquired secondary resistance, and rarely detected in primary resistant tumors (<5.0%). Interestingly, S768I EGFR mutation (also in exon 20) confers little or no response to first-generation TKIs, but a great probability to respond to second-generation TKIs or Afatinib[17]. Afatinib therapeutic choice has been extended to include patients with NSCLC in metastatic setting whose tumors harbor rare EGFR mutations, such as G719X, L861Q, and S768I.

In our study, 45.0% of mutations detected in EGFR happen in exon 19 by distinct small deletions, including complex in-frame deletion p.E746_T751>A, first described here. Point mutations frequencies in exon 18 (G719A, n = 1) and exon 21 (L858R, n=5 e L861Q, n=2) were 40.0%, and 15.0% in exon 20 (all S768I). These findings are in agreement with frequencies in literature[18], except for S768I mutation that is rare in other series (0.55%)[18], but happen in 15.0% (three cases) in our study. The differences in risk factors or our population genetic background may explain this. In one case, exon 18 EGFR point mutation G719A was detected concomitantly with KRAS mutation G12C in the same sample.

This rare finding may be explained by intratumoral heterogenicity (by mutational events arising separately in at least two distinct clones), or because of two co-mutational events into a unique malignant cellular clone leading to EGFR pathway cooperative activation in both upstream and downstream of the RAS-RAF-MEK-MAPK signalingpathway. Unfortunately, we could not repeat the analysis in this case due insufficient tissue remaining. A recent study including 17.664 lung cancer patients detected 2 to 3 concomitant driver mutations in almost 1% of the cases. The most common co-mutations occurred again with EGFR in this large cohort were PIK3CA (n=28), KRAS (n=24), ALK (n=10), and BRAF (n=5) mutations[19].

Recently in Brazil, government regulatory agency Agencia Nacional de Vigilância Sanitária (ANVISA) approved an oral third-generation irreversible EGFR TKI as front-line treatment for advanced NSCLC with EGFR exon 19 deletions or exon 21 L858R mutation. In the FLAURA study, a phase III randomized trial for advanced NSCLC[20], osimertinib was compared with first-generation TKIs (gefitinib or erlotinib) and it could improve PFS (18.9 versus 10.2 months; HR 0.46, 95% CI 0.37-0.57) and response duration (17.2 versus 8.5 months) with fewer toxicities.

Our study has limitations because it was retrospective and we excluded a large number of cases because of scarce or depleted tissue material and because of insufficient quality (fragmentation) of DNA extracted from FFPET. Based on current international guidelines all advanced adenocarcinoma NSCLC should be tested for actionable drug targets ( EGFR, ALK, and ROS1 )[2]. According to the College of American Pathologists[2], SCC patients can be tested for sensitivity mutations in case of uncertain of an adenocarcinoma component, especially when clinical features favored presence of EGFR mutation (female, never smoker or young patients). In our study, many blocks were scarce, and some could not be histologically reanalyzed, so we opted for including in our mutational test all NSCLC cases (adenocarcinoma and SCC). This may explain the low EGFR frequency in our study.

The analytical method sensitivity may also explain differences in EGFR mutational rates in literature. We choose pyrosequencing because of its sensitivity to detect a minimum of 5% mutated alleles. Recently, with the application of next generation sequencing (NGS) and other allele-specific-based assays, i.e. digital droplet polymerase chain reaction (ddPCR), sensitivity of much less than 1% have been feasible, allowing the screening of rare somatic mutated alleles in body fluids (plasma, urine) by liquid biopsy[21]. Thus, in situation of limited specimen, other laboratory platforms would be preferred to prevent falsenegative results.

Despite this fact, pyrosequencing is faster, requires less DNA, and is less complex in terms of assay design and technical setup than others techniques. It can determine not only known EGFR hotspots, including exon 19 deletions and codon 719 substitutions, but also new mutations, like complex in-frame deletion p.E746_T751>A. Ultimately, genetic laboratories must consider analytical sensitivity in their reports, mutational coverage and method limitations when evaluating EGFR mutation assays for adoption into the laboratory workflow. The small volume of viable tumor material for analysis demonstrates the importance of an excellent collection of tissue at the time of biopsy, storage, and the impact in sensitivity that liquid biopsy will bring in the next few years for molecular analysis of tumors.

Because the access of the SUS population to EGFR TKI was limited by cost, only two patients were treated with first generation TKI (Gefitinib). The absence of differences in NSCLC survival between the mutated and non-mutated EGFR groups treated with chemotherapy alone during a pre-TKI era suggests that they have similar biological behaviors, and that EGFR alone was not prognostic. Currently, in our hospital, we perform molecular analyzes (EGFR, ALK, PD-L1) in all patients with advanced NSCLC adenocarcinoma, in association with pharmaceutical companies, access to therapy with Gefitinib after detection of the EGFR mutation is provided by the hospital after negotiating spending with the drug.

We intend to evaluate in the future the impact of introducing EGFR TKI on our population overall survival. Considering that EGFR mutation frequency in our population was 15.7% and that in Brazilian literature mutated cases survival can vary from 30 to 60 months in best series[5], a pharmacoeconomical analysis focusing these new target therapies introduction in the context of public health is urgently needed. Recently, Brazilian Society of Clinical Oncology (SBOC) is assisting the Ministry of Health to select drugs according to scientific evidences available and cost-effectiveness analysis, in order to guarantee the equity in accessibility to Brazilian population treated in SUS[22]. Similar studies in Brazil will be important to characterize more widely NSCLC genetic profiling in other populations and EGFR TKI treatment impact magnitude on clinical outcomes.

Conflicts of interest

No Conflict of interest.

AUTHOR'S CONTRIBUTION

Thais Abreu Almeida: Collection and assembly of data, Conception and design, Data analysis and interpretation, Final approval of manuscript, Manuscript writing, Provision of study materials or patient.

Jeanine Marie Nardin: Collection and assembly of data, Data analysis and interpretation, Manuscript writing, Provision of study materials or patient.

Amanda Jurgensen: Collection and assembly of data, Provision of study materials or patient.

Janaina Takahashi: Collection and assembly of data, Provision of study materials or patient.

Juliana Jung: Provision of study materials or patient.

Graziele Losso: Collection and assembly of data, Data analysis and interpretation, Manuscript writing, Provision of study materials or patient.

José C. Casali-da-Rocha: Conception and design, Data analysis and interpretation, Final approval of manuscript, Manuscript writing.

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Corresponding author:

Publication History

Received: 29 October 2018

Accepted: 20 February 2019

Article published online:
15 April 2019

© 2022. This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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